Understand the wide scope of the civil engineering profession and the types of projects that you may contribute to in the future. Develop and strengthen key practical, professional and transferable skills that are required to meet the major challenges in society.

Develop essential engineering skills, working in groups and using problem-based learning to find solutions to real engineering projects

Build the mathematical knowledge, skills and techniques required throughout your civil engineering programme, and learn how mathematics is applied to help solve engineering problems.

Explore basic concepts in computer programming and numerical analysis and understand their importance within the discipline of civil engineering.

Learn the fundamental principles of mechanics, static and dynamic systems, and the different types of mechanics issues that can arise in civil engineering.

Examine the behaviour of common structural forms and how they carry external forces through the development of internal forces in structural elements.

Analyse the behaviour of commonly used civil engineering materials, and learn how to evaluate and select appropriate materials for different civil engineering applications.

Understand the physical processes governing the behaviour of fluids at rest and in motion, and gain insight into the practical world of civil engineering fluid mechanics.

Learn about fundamental soil mechanics and geotechnical engineering, geotechnical design principles and the importance of developing a detailed understanding of ground conditions in successful civil engineering.

Explore the interdisciplinary nature of major processes in energy and environmental engineering. Gain an overview of the fundamental science in disciplines such as microbiology, chemistry and thermodynamics, focusing on their application to energy technologies and the environment.

Work individually and within a team to develop, critique, defend and augment conceptual designs at multiple scales.

Equip yourself with an essential toolbox of applied mathematical techniques that can be used to solve real-world engineering problems.

Gain hands-on experience as you learn concepts of computer-assisted engineering, graphical presentation and programming. Solve a wide range of civil and environmental engineering problems using MATLAB.

Understand issues of uncertainty in civil and environmental engineering and learn how statistical tools are used to estimate uncertainty for different types of data.

Extend your knowledge of mechanics and structural mechanics and develop a deeper understanding of the physical behaviour of structural elements and systems.

Examine the structural design basis and behaviour of individual elements in both reinforced concrete structures and steel structures.

Broaden your understanding of fluid mechanics and the additional complexities associated with unsteady fluid flows, two-dimensional flows, and real (not ideal) fluids.

Learn the fundamental elements of soil and rock mechanics and the implications for engineering design, along with the associated geological histories and hazards.

Apply principles of hydrology and water engineering to understand the concepts and processes governing the natural and man-made water cycle.

Explore the business environment in which civil engineering projects take place, focusing on concepts such as risk management, supply chains, project management and procurement, worker safety and environmental impact.

Consolidate your technical knowledge through practical application as you work on a significant civil engineering design project. Gain teamwork skills and real-world insight into the design process through industrial partnering on the project.

Learn the principal computational methods for civil engineering and assess the accuracy of computer-based solutions within structural and geotechnical engineering, fluid mechanics and heat transfer.

Explore how structures reach the point of ultimate failure, and understand key issues regarding geometric and material nonlinearities, methods for analyses, and practical considerations of construction and safety.

Examine the basic principles of dynamics as applied to structural engineering, and learn how to formulate and solve engineering problems related to the modelling, design and assessment of structures subjected to dynamic action.

Extend your understanding of turbulent mixing and transport processes in fluid mechanics and understand their significance in areas of pollutant dispersion and in the modelling of natural and man-made hazards.

Build upon your knowledge of soil mechanics with this introduction to geotechnical design, focusing on slope stability analysis, foundation design and retaining wall design.

Uncover the fundamental principles for the design of drinking water supply and treatment works, wastewater collection and treatment systems, and strategies for waste and resource management.

Explore the design principles of transport systems and their application to the movement of people and goods within the wider context of the civil engineering profession.

Choose from a range of subjects hosted outside of the department and learn alongside students from other areas of study.

Learn how to apply systematic procedures for geometric and material nonlinear structural analysis, use advanced nonlinear analysis software and undertake stability and buckling analysis for multi-degree of freedom structural systems.

Explore the fundamental concepts and principles of the analysis and design of thin-walled shell-structures.

Understand the nearshore characteristics of waves, currents, tides and storm surges, and learn techniques for calculating the wave and current processes that occur in the coastal zone.

Explore the process of locating, designing, constructing and maintaining highways. Uncover concepts relating to speed limits, route location, horizontal and vertical alignment, pavement design, surface drainage and earthworks requirements for highway construction.   

Develop a sound understanding of concrete structure design and learn advanced design techniques such as stress field analysis and strut and tie modelling.

Learn the core principles of design in timber and masonry and develop your structural design skills in the conception and sizing of typical timber and masonry elements.

Study concepts such as traffic flow measurement and analysis, queuing theory, principles of traffic signal control, management of road user groups, motorway monitoring theory, and survey methods and data analysis techniques used by traffic engineers.

Undertake a specific piece of independent research in the form of a critical review, laboratory- or field-based experimental investigation, modelling/numerical analysis project, or a design-related project.

Explore operational research methods used in the systems approach to engineering and management, and the requisite tools for mathematical representation of decision-making problems.

Build upon your structural analysis knowledge to examine the design fundamentals of structural steelwork elements and the conceptual design of a range of structural framing systems.

Develop a sound understanding of concrete structure design and demonstrate the application of theory to practice through a design project.

Learn the fundamental principles of the structural behaviour and design criteria of prestressed concrete structures, and understand the mechanics that define its internal forces.

Enhance your understanding of fluid flows and fluid loading processes and investigate both steady and unsteady flows across a wide range of hydrodynamic civil applications.

Examine the main geotechnical hazards – landslides, volcanoes, tsunamis and earthquakes – and their potential damaging effects on the built environment, and learn the fundamental elements of engineering seismology, seismic hazard assessment and soil dynamics.

Interpret facets of soil behaviour for advanced design of geotechnical structures and explore the importance of computer-based geotechnical design calculations.

Reflect upon the fundamental concepts and design philosophies related to timber and masonry elements and harness your knowledge through the design of simple conventional structures.

Understand the key principles and emerging trends in the design, modelling and control of water supply and wastewater collection networks, and wastewater treatment processes.

Obtain the knowledge and skills to appraise water resources demand and availability, and devise engineering solutions needed for optimal resource management.

Learn the basic principles of waste and resource management in the context of civil engineering and gain knowledge and skills in the management, treatment, disposal and recycling options for solid waste.

Study concepts such as traffic flow measurement and analysis, queuing theory, principles of traffic signal control, management of road user groups, motorway monitoring theory, and survey methods and data analysis techniques used by traffic engineers.

Cultivate a rigorous mathematical understanding of the principal techniques used for modelling travel demand, transport supply, network performance and the appraisal of transport policies and projects.

Study the principal environmental impacts, risks and safety concerns of transport, and discover tools and techniques for evaluating the effects on air quality, noise and climate at local and global scales.

Our urban landscapes are becoming increasingly complex and populated, presenting broad-ranging challenges regarding the sustainability and resilience of cities and buildings. This module aims to equip students with techniques and understanding that is necessary for the prediction, design and control of flow systems in the built environment.

Understand the wide scope of the civil engineering profession and the types of projects that you may contribute to in the future. Develop and strengthen key practical, professional and transferable skills that are required to meet the major challenges in society.

Develop essential engineering skills, working in groups and using problem-based learning to find solutions to real engineering projects

Build the mathematical knowledge, skills and techniques required throughout your civil engineering programme, and learn how mathematics is applied to help solve engineering problems.

Explore basic concepts in computer programming and numerical analysis and understand their importance within the discipline of civil engineering.

Learn the fundamental principles of mechanics, static and dynamic systems, and the different types of mechanics issues that can arise in civil engineering.

Examine the behaviour of common structural forms and how they carry external forces through the development of internal forces in structural elements.

Analyse the behaviour of commonly used civil engineering materials, and learn how to evaluate and select appropriate materials for different civil engineering applications.

Understand the physical processes governing the behaviour of fluids at rest and in motion, and gain insight into the practical world of civil engineering fluid mechanics.

Learn about fundamental soil mechanics and geotechnical engineering, geotechnical design principles and the importance of developing a detailed understanding of ground conditions in successful civil engineering.

Explore the interdisciplinary nature of major processes in energy and environmental engineering. Gain an overview of the fundamental science in disciplines such as microbiology, chemistry and thermodynamics, focusing on their application to energy technologies and the environment.

Work individually and within a team to develop, critique, defend and augment conceptual designs at multiple scales.

Equip yourself with an essential toolbox of applied mathematical techniques that can be used to solve real-world engineering problems.

Gain hands-on experience as you learn concepts of computer-assisted engineering, graphical presentation and programming. Solve a wide range of civil and environmental engineering problems using MATLAB.

Understand issues of uncertainty in civil and environmental engineering and learn how statistical tools are used to estimate uncertainty for different types of data.

Extend your knowledge of mechanics and structural mechanics and develop a deeper understanding of the physical behaviour of structural elements and systems.

Examine the structural design basis and behaviour of individual elements in both reinforced concrete structures and steel structures.

Broaden your understanding of fluid mechanics and the additional complexities associated with unsteady fluid flows, two-dimensional flows, and real (not ideal) fluids.

Learn the fundamental elements of soil and rock mechanics and the implications for engineering design, along with the associated geological histories and hazards.

Apply principles of hydrology and water engineering to understand the concepts and processes governing the natural and man-made water cycle.

Explore the business environment in which civil engineering projects take place, focusing on concepts such as risk management, supply chains, project management and procurement, worker safety and environmental impact.

Consolidate your technical knowledge through practical application as you work on a significant civil engineering design project. Gain teamwork skills and real-world insight into the design process through industrial partnering on the project.

Learn the principal computational methods for civil engineering and assess the accuracy of computer-based solutions within structural and geotechnical engineering, fluid mechanics and heat transfer.

Explore how structures reach the point of ultimate failure, and understand key issues regarding geometric and material nonlinearities, methods for analyses, and practical considerations of construction and safety.

Examine the basic principles of dynamics as applied to structural engineering, and learn how to formulate and solve engineering problems related to the modelling, design and assessment of structures subjected to dynamic action.

Extend your understanding of turbulent mixing and transport processes in fluid mechanics and understand their significance in areas of pollutant dispersion and in the modelling of natural and man-made hazards.

Build upon your knowledge of soil mechanics with this introduction to geotechnical design, focusing on slope stability analysis, foundation design and retaining wall design.

Uncover the fundamental principles for the design of drinking water supply and treatment works, wastewater collection and treatment systems, and strategies for waste and resource management.

Explore the design principles of transport systems and their application to the movement of people and goods within the wider context of the civil engineering profession.

Choose from a range of subjects hosted outside of the department and learn alongside students from other areas of study.

Learn how to apply systematic procedures for geometric and material nonlinear structural analysis, use advanced nonlinear analysis software and undertake stability and buckling analysis for multi-degree of freedom structural systems.

Explore the fundamental concepts and principles of the analysis and design of thin-walled shell-structures.

Understand the nearshore characteristics of waves, currents, tides and storm surges, and learn techniques for calculating the wave and current processes that occur in the coastal zone.

Explore the process of locating, designing, constructing and maintaining highways. Uncover concepts relating to speed limits, route location, horizontal and vertical alignment, pavement design, surface drainage and earthworks requirements for highway construction.   

Develop a sound understanding of concrete structure design and learn advanced design techniques such as stress field analysis and strut and tie modelling.

Learn the core principles of design in timber and masonry and develop your structural design skills in the conception and sizing of typical timber and masonry elements.

Study concepts such as traffic flow measurement and analysis, queuing theory, principles of traffic signal control, management of road user groups, motorway monitoring theory, and survey methods and data analysis techniques used by traffic engineers.